Article
Silencing of a Germin-Like Protein Gene (CchGLP) in Geminivirus-Resistant Pepper (Capsicum chinense Jacq.) BG-3821 Increases Susceptibility to Single and Mixed Infections by Geminiviruses PHYVV and PepGMV Laura Mejía-Teniente 1,†,‡ , Ahuizolt de Jesús Joaquin-Ramos 2,† , Irineo Torres-Pacheco 1 , Rafael F. Rivera-Bustamante 3 , Lorenzo Guevara-Olvera 4,† , Enrique Rico-García 1 and Ramon G. Guevara-Gonzalez 1, * Received: 11 September 2015; Accepted: 12 November 2015; Published: 25 November 2015 Academic Editor: Thomas Hohn 1
2 3
4
* † ‡
C.A. Ingeniería de Biosistemas, Facultad de Ingeniería-Campus Amazcala, Carretera a Chichimequillas, Km. 1, S/N, El Marques, Queretaro C.P. 76229, Mexico;
[email protected] (L.M.-T.);
[email protected] (I.T.-P.);
[email protected] (E.R.-G.) Instituto Tecnológico de Roque, Departamento de Ingeniería en Industrias Alimentarias, Km. 8 Carr. Celaya-J. Rosas, Roque, Celaya, Gto C.P. 38110, Mexico;
[email protected] Departamento de Ingeniería Genética, Centro de Investigación y de Estudios Avanzados (CINVESTAV)-Unidad Irapuato, Carretera Irapuato-Leon, Km 9.6, Libramiento norte, Irapuato, Guanajuato A.P. 629, Mexico;
[email protected] Departamento de Ingeniería Bioquímica, Instituto Tecnológico de Celaya, Ave. Tecnológico y A, Garcia-Cubas, S/N, Col. FOVISSSTE, Celaya, Gto A.P. 57, Mexico;
[email protected] Correspondence:
[email protected]; Tel.: +52-442-192-1200 These authors contributed equal to this work. Present address: Universidad de Guanajuato, Campus Celaya-Salvatierra, División de Ciencias de la Salud e Ingenierías, Departamento de Ingeniería Agroindustrial, Programa de Ingeniería en Biotecnología, Av. Mutualismo Esq. Prolongación Río Lerma S/N, Celaya, Gto. C.P. 38060, Mexico; Tel.: +52-461-614-6440.
Abstract: Germin-like proteins (GLPs) are encoded by a family of genes found in all plants, and in terms of function, the GLPs are implicated in the response of plants to biotic and abiotic stresses. CchGLP is a gene encoding a GLP identified in a geminivirus-resistant Capsicum chinense Jacq. accession named BG-3821, and it is important in geminivirus resistance when transferred to susceptible tobacco in transgenic experiments. To characterize the role of this GLP in geminivirus resistance in the original accession from which this gene was identified, this work aimed at demonstrating the possible role of CchGLP in resistance to geminiviruses in Capsicum chinense Jacq. BG-3821. Virus-induced gene silencing studies using a geminiviral vector based in PHYVV component A, displaying that silencing of CchGLP in accession BG-3821, increased susceptibility to geminivirus single and mixed infections. These results suggested that CchGLP is an important factor for geminivirus resistance in C. chinense BG-3821 accession. Keywords: VIGS; Germin-like proteins
plant-virus
interaction;
resistance;
Mn-SOD;
transient
expression;
PACS: J0101
Viruses 2015, 7, 6141–6151; doi:10.3390/v7122930
www.mdpi.com/journal/viruses
Viruses 2015, 7, 6141–6151
1. Introduction Geminiviridae is a plant virus family whose members infect important crops worldwide. These viruses contain single-stranded DNA genomes packed in twinned particles [1]. Family Geminiviridae comprises genera: Mastrevirus, Begomovirus, Curtovirus, Topocuvirus, Becurtovirus, Eragrovirus and Turncurtovirus [2,3]. Genus Begomovirus is the most widespread and diverse worldwide, causing crop losses ranging from 30% to 100% [4]. Pepper Huasteco Yellow Vein Virus (PHYVV) and Pepper Golden Mosaic Virus (PepGMV), are Begomoviruses widely distributed in Mexico, and considered major viral pathogens in pepper [5–7]. Accession BG-3821 of Capsicum chinense Jacq. was identified and characterized as a source of resistance to PHYVV and PepGMV [8–13]. Transcriptomic studies with accession BG-3821, identified a germin-like protein (GLP) gene called CchGLP, as involved in resistance to PHYVV and PepGMV [14]. CchGLP displayed a manganese-superoxide dismutase (Mn-SOD) in bacterial heterologous expression systems [15]. Transgenic expression of CchGLP in a geminivirus-susceptible tobacco cultivar (Nicotiana tabacum xanthi nc) provided resistance to geminivirus infections [7]. GLPs have been classified based on oxalate oxidase (OXO) or superoxide dismutase (SOD) activities [16]. GLP activity results in production of hydrogen peroxide, a reactive oxygen species (ROS) important in plant signaling to stress. Hydrogen peroxide is a signal for hypersensitive cell death [17,18]. Leaves of C. chinense accession BG-3821 displayed higher accumulation of ROS in comparison to susceptible accessions [13]. Virus-induced gene silencing (VIGS) is a virus vector technology that exploits RNA-mediated defense mechanisms in plants to specifically silence genes of interest [19]. Once plant cell become virus-infected, small interfering RNA (siRNA) is produced in the infected cell corresponding to parts of the viral vector genome, including any non-viral insert. VIGS technology is a powerful approach to functional genomics and to knock out function of a gene-of-interest [20]. The first RNA virus used as a silencing vector was Tobacco mosaic virus (TMV) [21]. Tobacco rattle virus (TRV) vectors have also been used in successful silencing studies of PDS and FLO genes (Phytoene desaturate and Floricaula genes respectively) in Cysticapnos vesicaria causing strong photobleaching of green parts and reduction of endogenous PDS transcript levels and affected floral phyllotaxis, symmetry and floral organ identities [22]. Infection with an apple latent spherical virus (ALSV) vector containing a fragment of soybean isoflavone synthase 2 (soyIFS2) gene reduced the levels of both soyIFS2- and soyIFS1-mRNAs and then the isoflavone content in cotyledons of mature seeds of infected soybean plants [23]. Rice tungro bacilliform virus (RTBV) has been developed as a rice-infecting virus containing DNA as the genetic material. Agroinoculation mediated transfection accumulated a full-length RTBV DNA cloned as a partial dimer in a binary plasmid and produced detectable RTBV coat proteins within two weeks of infection [24]. For VIGS studies in plants, geminiviruses present several advantages as their genome organization is conserved, so new geminiviruses can be easily exploited using basic knowledge available of these viruses [25]. The small genome of geminiviruses is very convenient for cloning and sequencing, and its propagation is simpler than the in vitro production of RNA. In addition, DNA is less labile than RNA, and can be directly inoculated, avoiding the need to use Agrobacterium as a carrier. Furthermore, DNA vectors have proven to be more stable than RNA vectors because they lack an RNA intermediate and, thus, are not targets for RNA degradation. Hence, even if their transcripts are silenced, the replicons continue to multiply and move, although at a slower rate than their wild type equivalents [20]. By contrast, RNA viruses induce a transient silencing that might result in the removal of the viral genome itself or in important differences in transcripts levels [26]. In this sense, a Pepper huasteco yellow vein virus (PHYVV-A)-derived vector, has been evaluated for silencing genes Comt, pAmt, and Kas in pepper plants which are involved in the biosynthesis of capsaicinoids. This approach was successful in silencing the aforementioned genes and leading to a dramatic reduction in capsaicinoid content [27]. Thus, the aim of this work was to evaluate the role of CchGLP in natural resistance to geminivirus in Capsicum chinense BG-3821 through silencing the gene using PHYVV-A derived vector.
6142
Viruses 2015, 7, 6141–6151
2. Materials and Methods
Viruses 2015, volume, page–page
2.1. Plant Growth
2. Materials and Methods
Capsicum chinense BG-3821 plants, previously characterized as resistant to geminivirus [8–10], were 2.1. Plant Growth employed for testing silencing of CchGLP. Seeds (supplied by CINVESTAV-Unidad Irapuato) Capsicum chinense BG‐3821 plants, previously characterized as resistant to geminivirus [8–10], were germinated in plastic pots (250 cm3 ) containing a sterile substrate (peat moss:vermiculite in were employed for testing silencing of CchGLP. Seeds (supplied by CINVESTAV‐Unidad Irapuato) 3:1 proportion), and grown in a chamber at 28 C under a photoperiod of 16/8 h light/dark. were germinated in plastic pots (250 cm3) containing a sterile substrate (peat moss:vermiculite in 3:1 proportion), and grown in a chamber at 28 °C under a photoperiod of 16/8 h light/dark. 2.2. Construction of Viral Vector for Silencing CchGLP
PHYVV-A (-C) vector cloned into the Hind III site of plasmid bluescript SK+ was kindly 2.2. Construction of Viral Vector for Silencing CchGLP provided by Dr. Rafael Rivera-Bustamante from CINVESTAV Unidad Irapuato, and previously PHYVV‐A (‐C) vector cloned into the Hind III site of plasmid bluescript SK+ was kindly evaluated for functional silencing in pepper plants [27]. To construct the silencing vector for CchGLP, provided by Dr. Rafael Rivera‐Bustamante from CINVESTAV Unidad Irapuato, and previously a fragment of 93 bp by PCR from 51 -end of CchGLP open reading frame (ORF) was produced, which evaluated for functional silencing in pepper plants [27]. To construct the silencing vector for CchGLP, did not belong to the cupin domain of the GLP, using initiators that contain the recognition sequence a fragment of 93 bp by PCR from 5′‐end of CchGLP open reading frame (ORF) was produced, which to thedid not belong to the cupin domain of the GLP, using initiators that contain the recognition sequence restriction enzyme Sty I, because this enzyme is within the coat protein (CP) gene of the viral vectorto the restriction enzyme Sty I, because this enzyme is within the coat protein (CP) gene of the viral PHYVV-A (-C). For this purpose, PCR oligonucleotides were designed from CchGLP cDNA vector PHYVV‐A (‐C). For this purpose, PCR oligonucleotides were designed from CchGLP cDNA (accession number DQ677335): 51 -ccttggTTGGCTACCCTAATCTTGAGCA-31 (forward primer) and 1 with the following amplification conditions: 94 C/1 min, (accession number DQ677335): 5′‐ccttggTTGGCTACCCTAATCTTGAGCA‐3′ (forward primer) and 51 ccaaggGCAAGAATAGCCACAAGGTGA-3 5′ccaaggGCAAGAATAGCCACAAGGTGA‐3′ with the conditions: 94 °C/1 63 C/1 min and 72 C/1 min by 35 cycles. Once the following amplification fragment of 93 bp was flanked by enzyme min, 63 °C/1 min and 72 °C/1 min by 35 cycles. Once the fragment of 93 bp was flanked by enzyme r 2.1-TOPOr TA Sty I, single bands of the expected size were cloned directly into the pCR Sty I, single bands of the expected size were cloned directly into the pCR® 2.1‐TOPO® TA vector— vector—subcloning vector (Invitrogen, Carlsbad, CA, USA, https://www.lifetechnologies.com [28]) subcloning vector (Invitrogen, Carlsbad, CA, USA, https://www.lifetechnologies.com [28]) as as indicated by the manufacturer protocol. Ligation tested in subcloning vector, the 93 bp fragment indicated by the manufacturer protocol. Ligation tested in subcloning vector, the 93 bp fragment was was cleaved with the restriction enzyme Sty I and this fragment was linked into the Sty I site of the cleaved with the restriction enzyme Sty I and this fragment was linked into the Sty I site of the vector vectorviral PHYVV‐A (‐C), resulting in the PHYVV::NC93 (see Figure 1). viral PHYVV-A (-C), resulting in the PHYVV::NC93 (see Figure 1).
Figure 1. Construct of PHYVV::NC93 (a PHYVV‐A for CchGLP Figure 1. Construct designdesign of PHYVV::NC93 (a PHYVV-A derivedderived vector) vector) for CchGLP silencing in silencing in C. chinense BG‐3821 plants. (A), wild type (wt) PHYVV component C. chinense BG-3821 plants. (A) wild type (wt) PHYVV component A; (B) PHYVV-A A; (-C)(B), vector PHYVV‐A (‐C) vector resulted from Sty I digestion of wt PHYVV component A; (C), resulted from Sty I digestion of wt PHYVV component A; (C) PHYVV::NC93 silencing vector carrying PHYVV::NC93 silencing vector carrying a 93 base pairs (bp) fragment of the 5’ region of a 93 base pairs (bp) fragment of the 5’ region of CchGLP ORF (section in yellow); (D) DNA sequence CchGLP ORF (section in yellow); (D), DNA sequence of the 93 bp from CchGLP ORF used of the 93 bp from CchGLP ORF used for silencing studies. Underlined are indicated the sequences for silencing studies. Underlined are indicated the sequences used for primers (in each used for primers (in each primer a Sty I site was included at the 51 region of each primer, see materials primer a Sty I site was included at the 5′ region of each primer, see materials and methods). and methods). PHYVV-A component is cloned in the Hind III of plasmid bluescript SK+. PHYVV‐A component is cloned in the Hind III of plasmid bluescript SK+. 3
6143
Viruses 2015, 7, 6141–6151
2.3. Inoculation of C. chinense BG-3821 Plants with Silencing Vector and Geminivirus Infections Inoculation of C. chinense BG-3821 with the silencing vector and the geminiviruses was carried out in 4–6 true leaves stage using high pressure biolistic according to [8]. The inoculation of plants was developed in two steps: (a) First, plants were inoculated with silencing vector (PHYVV-A (93 bp CchGLP) + wt PHYVV-B9; (b) then, 5 days after this inoculation, the same plants were inoculated with either wt components A and B of PHYVV and/or PepGMV. Control plants, were inoculated with empty vector PHYVV-A (-C) plus PHYVV-B and in some cases mock-inoculated only with plasmid blue script SK+. Before inoculation, viral genomes were excised from the plasmid vector before inoculation using HindIII or BamHI digestions for PHYVV or PepGMV, respectively [8]). Inoculated plants were then incubated under the same conditions used in germination. Moreover, a replica for each treatment using a manual low pressure biolistic gun was carried out in order to analyze the systemic silencing. For this latter studies, plants were only inoculated with full (93 bp CchGLP) or empty (-C) vector without wt PHYVV-B. All biolistic inoculations were essentially carried out according to [8]. The experimental unit size for each treatment was 30 plants; experiments were carried out by triplicate in independent assays. 2.4. Detection of Geminiviruses by PCR Total DNA extractions of the inoculated plants were carried out at 90 dpi with geminiviruses according to the modified method of Dellaporta [29]. The DNA obtained was used as a template in the PCR in order to analyze the movement of virus in inoculated plants. Specific oligonucleotides were used for each geminivirus: 240-51 -GGCTTATTTGTAATAAGAG-31 and 241-51 -GAATTAAAGGTA CATGGAC-31 to PHYVV, and JM23-51 -TGGTGTAGGACTCCAGCAGAGTC-31 and JM24-51 -TAGG CCCACACCTTGGTGACCAA-31 to PepGMV. These oligonucleotides flank the common region of PHYVV and PepGMV and amplify a fragment of 350 and 280 bp, respectively. The conditions used for both oligonucleotides were: 95 C/1 min, 53 C/1 min and 72 C/1 min by 35 cycles [5]. 2.5. Assessment CchGLP Gene Silencing in C. chinense BG-3821 The silencing assessment of the CchGLP gene was conducted in two phenological stages (30 and 90 dpi). The expression of CchGLP gene was assayed at 30 dpi and 90 dpi by means of the reverse transcriptase-mediated polymerase chain reaction (RT-PCR) using 1 µg total RNA from foliar tissue. Then, total RNA of silenced-and-infected, and control (non-silenced) plants were obtained using the TRIZOLr Reagent (Invitrogen), according to the manufacturer’s instructions. RNA integrity was verified by 1.2% agarose gel electrophoresis. The quantification and purity of total RNA were measured spectro-photometrically by relation of absorbance (260/280 nm). Later, the first cDNA chain of CchGLP of each plant sample was obtained by RT-PCR according to the manufacturer’s instructions (Superscript One-Step RT-PCR System; Invitrogen). Then the cDNA of CchGLP was amplified with specific oligonucleotides: 51 -TCTAGAATGTCTAAACTTATAATCT-31 , and 51 -GAGCTCCTAACCCTTGAGTTTCTT-31 as described by [7] Guevara-Olvera et al., that gave rise to a fragment of 612 bp, employing the following conditions: 94 C/5 min; followed by 30 cycles of 94 C/1 min, 60 C/1 min; finally 72 C for 7 min. 2.6. Evaluation of the Phenotypic Response The phenotypic response was analyzed daily once biolistic inoculation was carried out. Results were registered and reported at 30 and 90 dpi. The scale of severity for geminivirus disease used was according to [5,8]. 2.7. Statistical Analysis Data were subjected to analysis of variance by the general linear models (GLM) procedure, means comparison by Tukey’s test according to SAS methods [30].
6144
Viruses 2015, 7, 6141–6151 Viruses 2015, volume, page–page
3. Results 3. Results 3.1. Phenotypic Response in C. chinense BG-3821 CchGLP-Silenced Plants 3.1. Phenotypic Response in C. chinense BG‐3821 CchGLP‐Silenced Plants Figure 1 shows the PHYVV-A based vector used to silence CchGLP in C. chinense Jacq. BG-3821. Figure 1 shows the PHYVV‐A based vector used to silence CchGLP in C. chinense Jacq. BG‐3821. A 93 base pairs (bp) 5’ region of CchGLP ORF, was inserted into the Sty I sites within CP ORF A 93 base pairs (bp) 5’ region of CchGLP ORF, was inserted into the Sty I sites within CP ORF of of PHYVV-A. This bpregion regiondoes doesnot notinclude includehomologous homologous sections sections with with other other GLPs GLPs reported PHYVV‐A. This 93 93 bp reported elsewhere, including one one identified identified in transcriptomic studies elsewhere, including in the the transcriptomic studies where where CchGLP CchGLP was was originally originally observed (not shown). This latter consideration is important in order to specifically silence CchGLP observed (not shown). This latter consideration is important in order to specifically silence CchGLP with no other GLPs present in accession BG‐3821. It is worth mentioning that fragments of 103 and with no other GLPs present in accession BG-3821. It is worth mentioning that fragments of 103 and 535 bp of CchGLP were also evaluated with similar results, however the 93 bp fragment displayed 535 bp of CchGLP were also evaluated with similar results, however the 93 bp fragment displayed more stable results in this study, thus this fragment was chosen for CchGLP silencing studies reported more stable results in this study, thus this fragment was chosen for CchGLP silencing studies reported in this work (data not shown). in this work (data not shown). Figures 2 and 3 show the molecular and phenotypic analysis of typical CchGLP‐silenced plants Figures 2 and 3 show the molecular and phenotypic analysis of typical CchGLP-silenced plants with viral vector system based on PHYVV‐A, once single inoculated either with PHYVV (Figure 2A), with viral vector system based on PHYVV-A, once single inoculated either with PHYVV (Figure 2A), PepGMV (Figure (Figure 2B), 2B), or or mixed mixed inoculated inoculated (Figure (Figure 3). 3). Control with empty empty viral viral PepGMV Control plants plants inoculated inoculated with vector (PHYVV (‐C) + wt PHYVV component B), displayed no symptoms. Plants were evaluated 30 vector (PHYVV (-C) + wt PHYVV component B), displayed no symptoms. Plants were evaluated days post‐geminivirus inoculation (dpi). It is clearly shown that when CchGLP is silenced, (Figure 30 days post-geminivirus inoculation (dpi). It is clearly shown that when CchGLP is silenced, 2A,B), the phenotypic response in accession BG‐3821 is the appearance of symptoms in comparison (Figure 2A,B), the phenotypic response in accession BG-3821 is the appearance of symptoms in to non‐silenced control plants. comparison to non-silenced control plants.
Figure 2. Molecular and phenotypical analysis in C. chinense BG‐3821 using PHYVV::NC93 Figure 2. Molecular and phenotypical analysis in C. chinense BG-3821 using PHYVV::NC93 construction. lane 1, pBS mock‐inoculation; lane 2, lane PHYVV‐A (‐C); lane 3, construction. (A)(A), lane 1, pBS mock-inoculation; lane 2, PHYVV-A (-C); 3, PHYVV::NC93 silenced PHYVV::NC93 silenced plant; lane 4, − control; lane 5, + control; (B), lanes 1–5 corresponds plant; lane 4, control; lane 5, + control; (B) lanes 1–5 corresponds to the same treatments as in panel A.same In panels A and B, as thein bottom section at 30 days post-inoculation to the treatments panel A. In displays panels symptomatology A and B, the bottom section displays (dpi) of either PHYVV (panel A) or PepGMV (panel B) wt components A and B, respectively. symptomatology at 30 days post‐inoculation (dpi) of either PHYVV (panel A) or PepGMV Negative control corresponds to plants pBS mock-inoculated. Positive control samples came from (panel B) wt components A and B, respectively. Negative control corresponds to plants pBS plants sprayed with salicylic acid 0.01 mM, which is a potent CchGLP inductor as reported by [14]. mock‐inoculated. Positive control samples came from plants sprayed with salicylic acid 0.01 A housekeeping gene (gpdh, encoding glyceraldehyde phosphate dehydrogenase) was used as mM, which is a potent CchGLP inductor as reported by [14]. A housekeeping gene constitutive control. glyceraldehyde phosphate dehydrogenase) was used as constitutive (gpdh, encoding control.
6145 5
Viruses 2015, volume, page–page Viruses 2015, 7, 6141–6151 Viruses 2015, volume, page–page
Figure 3. Molecular and phenotypical analysis in C. chinense BG‐3821 using PHYVV::NC93 construction. Lane 1, pBS mock‐inoculation; lane 2, PHYVV‐A (‐C); lane 3, PHYVV::NC93 Figure 3. Molecular and phenotypical analysis in C. chinense BG‐3821 using PHYVV::NC93 Figure 3. Molecular and phenotypical analysis in C. chinense BG-3821 using PHYVV::NC93 silenced plant; lane 4, − control; lane 5, + control. Panel B, lanes 1–5 corresponds to the same construction. Lane 1, pBS mock‐inoculation; lane 2, PHYVV‐A (‐C); lane 3, PHYVV::NC93 construction. Lane 1, pBS mock-inoculation; lane 2, PHYVV-A (-C); lane 3, PHYVV::NC93 silenced plant; lane 4, in control; control. Panel B, lanes 1–5 corresponds to displayed at 30 the same treatments as silenced plant; lane 4, − control; lane 5, + control. Panel B, lanes 1–5 corresponds to the same treatments as panel lane A. 5, In +the bottom section symptomatology is days in panel A. In the section symptomatology is displayed at 30 days post-inoculation of mixed post‐inoculation of mixed infection by both PHYVV and PepGMV wt components A and B. treatments as in bottom panel A. In the bottom section symptomatology is displayed at 30 days infection bycontrol both PHYVV and PepGMV wt components A and B. Negative control corresponds to Negative corresponds to plants pBS mock‐inoculated. Positive control samples post‐inoculation of mixed infection by both PHYVV and PepGMV wt components A and B. plants pBS control mock-inoculated. Positive control pBS samples came from plantsPositive sprayed with salycilic acid came from plants sprayed with salycilic acid 0.01 mM, which is a potent CchGLP inductor Negative corresponds to plants mock‐inoculated. control samples 0.01 mM, which a potent CchGLP inductor as (gpdh, reportedencoding by [14]. A housekeeping gene (gpdh, as reported by is[14]. A housekeeping gene glyceraldehyde phosphate came from plants sprayed with salycilic acid 0.01 mM, which is a potent CchGLP inductor encoding glyceraldehyde phosphate dehydrogenase) was used as constitutive control. dehydrogenase) was used as constitutive control. as reported by [14]. A housekeeping gene (gpdh, encoding glyceraldehyde phosphate dehydrogenase) was used as constitutive control. It is is important important to to mention mention that that in in this this work, work, 80% 80% of of inoculated-plants inoculated‐plants with with silencing silencing vector vector It displayed no CchGLP CchGLP expression throughout the plant plant of (indicating successful silencing; data not It is important to mention that in this work, 80% inoculated‐plants with silencing vector displayed no expression throughout the (indicating successful silencing; data not shown). Thus, results Figures and to silenced plants, in in order to to data evaluate displayed no CchGLP expression the plant (indicating successful silencing; not shown). Thus, results in in Figures 2 2throughout and 3 3 correspond correspond to these these silenced plants, order evaluate further their phenotype. In all cases CchGLP expression was silenced, plants became susceptible to shown). Thus, results in Figures 2 and 3 correspond to these order to evaluate further their phenotype. In all cases CchGLP expression was silenced silenced,plants, plantsin became susceptible geminivirus single and mixed infections (Figures 2 and 3). Typical symptomatology in upper leaves further their phenotype. In all cases CchGLP expression was silenced, plants became susceptible to to geminivirus single and mixed infections (Figures 2 and 3). Typical symptomatology in upper at 30 and days post‐geminivirus inoculation in CchGLP‐silenced plants is isshown 4. geminivirus single and mixed infections (Figures 2 and 3). Typical symptomatology in upper leaves leaves at 3090 and 90 days post-geminivirus inoculation in CchGLP-silenced plants shownin in Figure Figure 4. Symptoms increased in severity from 30 to 90 dpi both in single and mixed infections. Control plants at 30 and 90 days post‐geminivirus in CchGLP‐silenced plants is shown in Figure 4. Symptoms increased in severity from inoculation 30 to 90 dpi both in single and mixed infections. Control plants (inoculated with empty PHYVV‐A vector, and and then then infected infected with with wild wild type type geminivirus), did not not Symptoms increased in severity from 30 to 90 dpi both in single and mixed infections. Control plants (inoculated with empty PHYVV-A vector, geminivirus), did show any symptoms in these experiments (Figure 4). (inoculated with empty PHYVV‐A vector, (Figure and then show any symptoms in these experiments 4). infected with wild type geminivirus), did not show any symptoms in these experiments (Figure 4).
Figure 4. Typical symptoms in upper leaves of CchGLP‐silenced C. chinense BG‐3821 at 30
Figure 4. Typical symptoms in upper leaves of CchGLP-silenced C. chinense BG-3821 at 30 and 90 dpi
Figure 4. Typical symptoms in upper leaves of CchGLP‐silenced C. chinense BG‐3821 at 30 and 90 dpi with PHYVV, PePGMV and mixed infections. Control means plants inoculated with PHYVV, PePGMV and mixed infections. Control means plants inoculated only with empty only with empty PHYVV‐A vector + wt component B and then PHYVV and PepGMV mixed and 90 dpi with PHYVV, PePGMV and mixed infections. Control means plants inoculated PHYVV-A vector + wt component B and then PHYVV and PepGMV mixed infected. infected. only with empty PHYVV‐A vector + wt component B and then PHYVV and PepGMV mixed infected. 6 6146 6
Viruses 2015, volume, page–page Viruses 2015, 7, 6141–6151 Viruses 2015, volume, page–page
This latter result indicated that phenotypic response of BG‐3821 CchGLP‐silenced plants increased symptomatology when that geminivirus‐infected. These of results suggested that CchGLP was This latter result indicated phenotypic response BG‐3821 CchGLP‐silenced plants This latter result indicated that phenotypic response of BG-3821 CchGLP-silenced plants still silenced at 90 dpi, and support the hypothesis of the role of CchGLP as an important factor for increased symptomatology when geminivirus‐infected. These results suggested that CchGLP was increased symptomatology when geminivirus-infected. These results suggested that CchGLP was geminivirus‐resistance in C. chinense BG‐3821. still silenced at 90 dpi, and support the hypothesis of the role of CchGLP as an important factor for still silenced at 90 dpi, and support the hypothesis of the role of CchGLP as an important factor for geminivirus‐resistance in C. chinense BG‐3821. geminivirus-resistance in C. chinense BG-3821. 3.2. Analysis of Systemic Silencing of CchGLP 3.2. Analysis of Systemic Silencing of CchGLP 3.2. Analysis of Systemic Silencing of CchGLP The systemic silencing verified in plants inoculated by low pressure biolistic due to the shot is specifically directed to a specific leaf in the plant. Thus, upper and lower non‐inoculated leaves were The systemic silencing verified in plants inoculated by low pressure biolistic due to the shot is The systemic silencing verified in plants inoculated by low pressure biolistic due to the shot is analyzed for CchGLP expression. Figure 5 displays the results of CchGLP expression in upper and specifically directed to a specific leaf in the plant. Thus, upper and lower non‐inoculated leaves were specifically directed to a specific leaf in the plant. Thus, upper and lower non-inoculated leaves were lower leaves. As shown, both in upper and lower leaves CchGLP expression was detected in the cases analyzed for CchGLP expression. Figure 5 displays the results of CchGLP expression in upper and analyzed for CchGLP expression. Figure 5 displays the results of CchGLP expression in upper and of expected gene expression (Figure 5, lanes 1, 2, and 5). In this sense, CchGLP silencing at 90 dpi was lower leaves. As shown, both in upper and lower leaves CchGLP expression was detected in the cases lower leaves. As shown, both in upper and lower leaves CchGLP expression was detected in the still after gene the full‐silencing vector 5,was inoculated 5, lanes and 4). It is worth of expected gene expression (Figure 5, lanes 1, 2, and 5). In this sense, CchGLP silencing at 90 dpi was casespresent of expected expression (Figure lanes 1, 2, and(Figure 5). In this sense,3 CchGLP silencing at mentioning that 95% of CchGLP‐silenced and then becoming geminivirus‐susceptible plants, kept still present after the full‐silencing vector was inoculated (Figure 5, lanes 3 and 4). It is worth 90 dpi was still present after the full-silencing vector was inoculated (Figure 5, lanes 3 and 4). It is the susceptible phenotype at during 90 dpi in then both becoming single and mixed infections. Thus, the mentioning that 95% of 95% CchGLP‐silenced and then becoming geminivirus‐susceptible plants, kept worth mentioning that of least CchGLP-silenced and geminivirus-susceptible plants, systemic silencing of CchGLP even at 90 dpi suggests that in these cases this could be the explanation the phenotype at least during 90 dpi in in both single keptsusceptible the susceptible phenotype at least during 90 dpi both singleand andmixed mixedinfections. infections. Thus, Thus, the the of the phenotype. However, the rest 5% of these originally‐silenced and geminivirus‐susceptible systemic silencing of CchGLP even at 90 dpi suggests that in these cases this could be the explanation systemic silencing of CchGLP even at 90 dpi suggests that in these cases this could be the explanation plants showed a slight expression of the CchGLP gene, and came to display slight symptoms in newly of of the the phenotype. phenotype. However, However,the therest rest 5% 5% of of these these originally‐silenced originally-silenced and and geminivirus‐susceptible geminivirus-susceptible developed leaves, corresponding with a glitch in CchGLP‐silencing in these plants (not shown). plants showed a slight expression of the CchGLP gene, and came to display slight symptoms in newly plants showed a slight expression of the CchGLP gene, and came to display slight symptoms in newly developed leaves, corresponding with a glitch in CchGLP‐silencing in these plants (not shown). developed leaves, corresponding with a glitch in CchGLP-silencing in these plants (not shown).
Figure 5. Silencing of CchGLP at 90 dpi in originally inoculated and non‐inoculated leaves in C. chinense BG‐3821 plants. Lanes 1–2, upper and lower leaves in inoculations with empty Figure 5. Silencing of CchGLP at 90 dpi in originally inoculated and non‐inoculated leaves Figure 5. Silencing of CchGLP at 90 dpi in originally inoculated and non-inoculated leaves in viral vector, respectively. Lanes 3–4 2,upper lower leaves of plants inoculated C. chinense BG-3821 plants. Lanes 1 and upper and and lower leaves in inoculations with emptywith viral in C. chinense BG‐3821 plants. Lanes 1–2, upper and lower leaves in inoculations with empty silenced vector for CchGLP, respectively. Lane 5, + control (geminivirus mixed infected vector, respectively; Lanes 3 and 4 upper and lower leaves of plants inoculated with silenced vector for viral vector, respectively. Lanes 3–4 upper and lower leaves of plants inoculated with BG‐3821 plant); for lane 6 5,− + control (inoculated only (geminivirus with empty vector). The CchGLP, respectively; Lane control (geminivirus infected BG-3821 plant);mixed lane 6 control silenced vector CchGLP, respectively. Lane mixed 5, plant + control infected (inoculated plant only with empty vector). The housekeeping gene gpdh (encoding glyceraldehyde housekeeping gene gpdh (encoding glyceraldehyde phosphate dehydrogenase) was used BG‐3821 plant); lane 6 − control (inoculated plant only with empty vector). The phosphate dehydrogenase) was used as control. as control. housekeeping gene gpdh (encoding glyceraldehyde phosphate dehydrogenase) was used as control. To verify the presence of geminiviruses throughout the evaluated plants, detection studies of To verify the presence of geminiviruses throughout the evaluated plants, detection studies of geminiviral DNA in apical and basal leaves were carried out (Figure 6). These results indicated the geminiviral DNA in apical and basal leaves were carried out (Figure 6). These results indicated the To verify the presence of geminiviruses throughout the evaluated plants, detection studies of movement mixed infected infected plants. movement and and replication replication of of these these viruses viruses either either in in single single or or mixed plants. These These results results geminiviral DNA in apical and basal leaves were carried out (Figure 6). These results indicated the agree with those reported elsewhere [8,9]. agree with and thosereplication reported elsewhere [8,9]. either in single or mixed infected plants. These results movement of these viruses agree with those reported elsewhere [8,9].
Figure 6. Detection by PCR of common region of PHYVV and PepGMV at 90 dpi in lower Figure 6. Detection by PCR of common region of PHYVV and PepGMV at 90 dpi in lower and upper leaves in C. chinense BG-3821 either in single or mixed infections. Lanes 1 and 3, lower and upper and upper leaves in C. chinense BG‐3821 either in single or mixed infections. Lanes 1 and 3, Figure 6. Detection by PCR of common region of PHYVV and PepGMV at 90 dpi in lower leaves in silenced plants, respectively; Lanes 2 and 4, lower and upper leaves in no-silenced plants. lower and upper leaves in silenced plants, respectively. Lanes 2 and 4, lower and upper and upper leaves in C. chinense BG‐3821 either in single or mixed infections. Lanes 1 and 3, In the bottom section, lane 1, positive control of wt PepGMV component A (280 bp); lane 2, PHYVV leaves in no‐silenced plants. In the bottom section, lane 1, positive control of wt PepGMV lower and upper leaves in silenced plants, respectively. Lanes 2 and 4, lower and upper Component A (350 bp); Lane 3, negative control, of DNA from a pBS mock-inoculated plant; lane 4, component A (280 bp), lane 2, PHYVV Component A (350 bp). Lane 3, negative control, of leaves in no‐silenced plants. In the bottom section, lane 1, positive control of wt PepGMV negative control of un-inoculated plant. DNA from a pBS mock‐inoculated plant; lane 4, negative control of un‐inoculated plant. component A (280 bp), lane 2, PHYVV Component A (350 bp). Lane 3, negative control, of
DNA from a pBS mock‐inoculated plant; lane 4, negative control of un‐inoculated plant. 7 6147 7
Viruses 2015, 7, 6141–6151
3.3. Severity of Disease Analysis The severity of disease caused by geminiviruses in silenced and non-silenced CchGLP plants was evaluated (Table 1). In general it was shown that CchGLP-silenced plants displayed a significant increase in severity in comparison to non-silenced plants. However, when compared to susceptible accessions of C. chinense (UX-SMH 1), the severity levels were milder, suggesting that CchGLP is not the only factor determining geminivirus resistance in C. chinense Jacq. BG-3821 (Table 1). Table 1. Severity * of disease in silenced and non-silenced C. chinense BG-3821 plants.
Treatment
PHYVV PepGMV Mixed: PHYVV + PepGMV Mock-inoculated (empty viral vector + wt PHYVV component B)
Severity in CchGLP Silenced C. chinense BG-3821 30 dpi 3b 3b 4a 0c
Severity in CchGLP Non-Silenced C. chinense BG-3821 Plants
90 dpi 5b 6a 6a
30 dpi 0a 0a 0a
0c
0a
90 dpi 0b 1a 1a 0b
Severity in Susceptible C. chinense Plants (Accession UX-SMH-1) 30 dpi 5c 7a 6b 0d
90 dpi 8b 9a 9a 0c
* Severity is according to a scale reported [5,8]. Data shown are the average of 60 plants analyzed in three independent experiments. Different letters in each column for each dpi designates a significant difference (Tukey p < 0.05).
4. Discussion In summary, the aforementioned results suggested that the GLP protein encoded by CchGLP of C. chinense BG-3821 could be actively participating in the defense mechanism of these plants due to in non-silenced plants inoculated with the empty vector (PHYVV (-C) + wt component B), resistance was displayed to simple and mixed infection with geminiviruses, and this phenotype became susceptible when silencing CchGLP. Moreover, in [7] we showed that CchGLP gene supported the resistance, either by attenuation and delay of symptoms, in single and mixed geminivirus infections in geminivirus-susceptible Nicotiana tabacum xanthi nc transgenic plants.Previous studies have shown the high expression of CchGLP gene in plant-geminivirus interaction in C. chinense BG-3821, as well as using salicylic acid (SA) as an inductor [12,14,15]. Park et al. [31] showed a similar pattern of expression of CaGLP1 in inoculated plants with TMV-Po virus, and they suggested that the transcript of CaGLP1 gene could be involved in the defense response of plants, which was caused by the compatible interaction between resistant plants and avirulent pathogens. Additionally, they [31] observed a rapid accumulation of CaGLP1 transcripts by SA 6 h after the induction. In the case of accession BG-3821, at least 2 h after the induction with SA, the expression of CchGLP gene was detected [12]. According to the results obtained either at 30 and 90 dpi, the efficiency of silencing was kept to the flowering stage in most of the silenced plants (95%). The lack of expression of CchGLP after the silencing and the phenotypic events of susceptibility generated by viral infection in silenced plants suggested that CchGLP could be part of the resistance mechanism or one of the main elements of this mechanism against geminiviruses in accession BG-3821. A better explanation for this event of susceptibility might be related to the levels of H2 O2 in cells. According to Lou et al. [32,33], the silencing of a GLP from Nicotiana attenuata significantly decreased the H2 O2 production. These authors demonstrated that H2 O2 induction by oral secretion of the mean depredator of Nicotiana attenuata, Manduca sexta protected the plants against the pest; however, silencing a GLP in Nicotiana attenuata stimulated its depredator activity [29]. H2 O2 is a molecule that is generated by SOD activities during an oxidative burst and is important in signaling against stress in plants [18]. H2 O2 signaling pathway reacts to different stimuli, such as biotic and abiotic, plant hormones (i.e., SA) and, to processes of cell division and cell growth [33]. Furthermore, it can activate defense genes involved in the production of the biochemical arsenal of defense in the plants against stress. We analyzed the resistance to geminivirus in transgenic plants of Nicotiana tabacum xanthi nc expressing 6148
Viruses 2015, 7, 6141–6151
CchGLP [7], which is highly susceptible to PHYVV and PepGMV infections. The results showed that transgenic lines of N. tabacum xanthi nc presented delay and amelioration of symptoms while the non-transgenic control was highly susceptible and its production of H2 O2 was lower than in transgenic lines.Together these results suggested that in absence of CchGLP expression, the Mn-SOD activities associated is null, causing a decrement of H2 O2 levels in cells. Therefore, the lack of CchGLP expression might decrease the response signals to geminivirus in Capsicum chinense BG-3821. Park et al. [31] observed a similar response generated by CaGLP1 gene, which was induced by TMV-Po virus, and they located the CaGLP1 transcripts in the cellular surface of Capsicum annuum. Likewise, it is suggested that CchGLP accompanies stress response and is associated with the development of the general mechanism of defense against pathogens. 5. Conclusions Taken together these results, it is concluded that CchGLP is an important component in the resistance to geminiviruses in C. chinense accession BG-3821. Acknowledgments: Authors thanks to FORDECYT (193512) and Ciencia Basica (SEP-CONACYT 2012, clave 178429) for funding support of this research. Author Contributions: Laura Mejía-Teniente, carried out the majority of the experiments reported in this paper and contributed also in the design of them; Ahuizolt de Jesus Joaquin-Ramos carried out viral vector. constructions; Irineo Torres-Pacheco, help in discussion related with systemic studies; Rafael F. Rivera-Bustamante and L. Guevara-Olvera contributed helping with some comments related to this research, experiments design and helping with some facilities in his Institution; Enrique Rico-Garcia help in the design of some experiments in greenhouse; Ramon G. Guevara-Gonzalez, conceive the idea of this research. Conflicts of Interest: The authors declare no conflict of interests.
References 1.
2.
3.
4.
5.
6.
7.
8.
Góngora-Castillo, E.; Ibarra-Laclette, E.; Diana, L.; Trejo-Saavedra, D.L.; Rivera-Bustamante, R.F. Transcriptome analysis of symptomatic and recovered leaves of geminivirus-infected pepper (Capsicum annuum). Virol. J. 2012, 9, 295–299. [CrossRef] [PubMed] Hanley-Bowdoin, L.; Bejarano, E.R.; Dominique Robertson, D.; Mansoor, S. Geminiviruses: Masters at redirecting and reprogramming plant processes. Nat. Rev. Microbiol. 2013, 11, 777–788. [CrossRef] [PubMed] Varsani, A.; Navas-Castillo, J.; Moriones, E.; Hernandez-Zepeda, C.; Idris, A.; Brown, J.K.; Murilo-Zerbini, F.; Martin, D.P. Establishment of three new genera in the family Geminiviridae: Becurtovirus, Eragrovirus and Turncurtovirus. Arch. Virol. 2014, 159, 2193–2203. [CrossRef] [PubMed] Lugo-Melchor, O.Y.; Guzmán-Uriarte, R.; García-Estrada, R.S.; Félix, J.L. Geminivirus Transmitidos por Mosca Blanca (Bemisia tabaci) en Tomate, en el Valle Agrícola de Culiacán, Sinaloa. Rev. Mex. Fitopatol. 2011, 29, 109–118. Torres-Pacheco, I.; Garzón-Tiznado, J.A.; Brown, J.K.; Becerra-Flora, A.; Rivera-Bustamante, R.F. Detection and distribution of geminiviruses in Mexico and Southern United States. Phytopathology 1996, 86, 1186–1192. [CrossRef] De La Torre-Almaráz, R.; Valverde, R.; Méndez-Lozano, J.; Ascencio-Ibañez, J.T.; Rivera-Bustamante, R.F. Caracterización preliminar de un geminivirus en tomate de cáscara (Physalis ixocarpa B.) en la región centro de Mexico. Agrociencia 2002, 36, 471–481. Guevara-Olvera, L.; Ruíz-Nito, M.L.; Rangel-Cano, R.M.; Torres-Pacheco, I.; Rivera-Bustamante, R.F.; Muñoz-Sánchez, C.I.; González-Chavira, M.M.; Cruz-Hernandez, A.; Guevara-Gonzalez, R.G. Expression of a germin-like protein gene (CchGLP) from a geminivirus-resistant pepper (Capsicum chinense Jacq.) enhances tolerance to geminivirus infection in transgenic tobacco. Physiol. Mol. Plant Pathol. 2012, 78, 45–50. [CrossRef] Godínez-Hernández, Y.; Anaya-López, J.L.; Díaz-Plaza, R.; González-Chavira, M.; Torres-Pacheco, I.; Rivera-Bustamante, R.F.; Guevara-González, R.G. Characterization of resistance to pepper huasteco geminivirus in chili peppers from Yucatán, Mexico. Hortscience 2001, 36, 139–142.
6149
Viruses 2015, 7, 6141–6151
9.
10.
11.
12.
13. 14.
15.
16. 17.
18.
19. 20. 21. 22.
23.
24. 25. 26.
Anaya-López, J.L.; Godínez-Hernández, Y.; Muñoz-Sánchez, C.I.; Guevara-Olvera, L.; Guevara-González, R.G.; Rivera-Bustamante, R.F.; González-Chavira, M.M.; Torres-Pacheco, I. Identification of resistance to single and mixed infections of pepper golden mosaic virus PepGMV and the Huasteco pepper virus in chilli peppers (Capsicum chinense Jaq.). Rev. Chapingo Ser. Hortic. 2003, 9, 225–234. Anaya-López, J.L.; González-Chavira, M.; Pons-Hernández, J.L.; Garzón-Tiznado, J.A.; Torres-Pacheco, I.; Rivera-Bustamante, R.F.; Hernández-Verdugo, S.; Guevara-González, R.G.; Muñoz-Sánchez, C.I.; Guevara-Olvera, L. Resistance to geminivirus mixed infections in Mexican wild peppers. Horscience 2003, 38, 251–255. Anaya-López, J.L.; Pérez-Mora, E.; Torres-Pacheco, I.; Muñoz-Sánchez, C.I.; Guevara-Olvera, L.; González-Chavira, M.M.; Ochoa-Alejo, N.; Rivera-Bustamante, R.F.; Guevara-González, R.G. Inducible gene expresión by Pepper huasteco virus in Capsicum chinense plants with resistance to geminivirus infections. Can. J. Plant Pathol. 2005, 27, 276–282. [CrossRef] Gasca-González, M.R.; Rivera-Herrera, Y.; Torres-Pacheco, I.; González-Chavira, M.M.; Guevara-Olvera, L.; Muñoz-Sánchez, C.I.; Guevara-González, R.G. Study on the transcripto in Capsicum chinense Jacq. resistant to Pepper Huasteca Yellow Vein Virus (PHYVV). Agrociencia 2008, 42, 107–117. García-Neria, M.A.; Rivera-Bustamante, R.F. Characterization of geminivirus resistance in an accession of Capsicum chinense Jacq. Mol. Plant-Microbe Int. 2011, 24, 172–182. [CrossRef] Barrera-Pacheco, A.; Joaquín-Ramos, A.; Torres-Pacheco, I.; Gonzalez-Chavira, M.; Perez-Perez, C.; Guevara-Olvera, L.; Guevara-Gonzalez, R.G. Analysis of transcriptional expression induced in Capsicum chinense BG-3821 under conditions of biotic and abiotic stress. Agrociencia 2008, 42, 95–106. León-Galvan, F.; de Jesus Joaquin-Ramos, A.; Torres-Pacheco, I.; Barba de la Rosa, A.P.; Guevara-Olvera, L.; Gonzalez-Chavira, M.M.; Ocampo-Velozquez, R.V.; Rico-García, E.; Guevara-González, R.G. A Germin-like protein gene (CchGLP) of Capsicum chinense Jacq. is induced during incompatible interactions and display Mn-superoxide dismutase activity. Int. J. Mol. Sci. 2011, 12, 7301–7313. [CrossRef] [PubMed] Dunwell, J.; Gibbings, J.G.; Mahmood, T.; Saqlan Naqvi, S.M. Germin and Germin-like Proteins: Evolution, Structure, and Function. Crit. Rev. Plant Sci. 2008, 27, 342–375. [CrossRef] Mejía-Teniente, L.; Torres-Pacheco, I.; González-Chavira, M.M.; Ocampo-Velázquez, R.V.; Herrera-Ruiz, G.; Chapa-Oliver, A.M.; Guevara-González, R.G. Use of elicitors as an approach for sustainable agriculture. Afr. J. Biotechnol. 2010, 9, 9155–9162. Mejía-Teniente, L.; Durán-Flores, F.D.; Chapa-Oliver, A.M.; Torres-Pacheco, I.; Cruz-Hernández, A.; González-Chavira, M.M.; Ocampo-Velozquez, R.V.; Guevara-González, R.G. Oxidative and molecular responses in Capsicum annuum L. after hydrogen peroxide, salicylic acid and chitosan foliar applications. Int. J. Mol. Sci. 2013, 14, 10178–10196. [CrossRef] [PubMed] Gupta, B.; Saha, J.; Sengupta, A.; Gupta, K. Recent advances on Virus Induced Gene silencing (VIGS): Plant functional genomics. Plant Biochem. Physiol. 2013, 1, 1–2. [CrossRef] Carrillo-Tripp, J.; Shimada-Beltrán, H.; Rivera-Bustamante, R.F. Use of geminiviral vectors for functional genomics. Curr. Opin. Plant Biol. 2006, 9, 209–215. [CrossRef] [PubMed] Godge, M.R.; Purkayastha, A.; Dasgupta, I.; Kumar, P. Virus-Induced gene silencing for functional analysis of selected genes. Plant Cell Rep. 2008, 27, 209–219. [CrossRef] [PubMed] Hidalgo, O.; Bartholmes, C.; Gleisberg, S. Virus-induced gene silencing (VIGS) in Cysticapnos vesicaria, a zygomorphic-flowered Papaveraceae (Ranunculales, basal eudicots). Ann. Bot. 2012, 109, 911–920. [CrossRef] [PubMed] Yamagishi, N.; Yoshikawa, N. Virus-induced gene silencing in soybean seeds and the emergence stage of soybean plants with apple latent spherical virus vectors. Plant Mol. Biol. 2009, 71, 15–24. [CrossRef] [PubMed] Purkayastha, A.; Mathur, S.; Verma, V.; Sharma, S.; Dasgupta, I. Virus-induced gene silencing in rice using a vector derived from DNA virus. Planta 2010, 232, 1531–1540. [CrossRef] [PubMed] Turnage, M.A.; Muangsan, N.; Peele, C.G.; robertson, D. Geminivirus-based vectors for gene silencing in Arabidopsis. Plant J. 2002, 30, 107–114. [CrossRef] [PubMed] Muangsan, N.; Beclin, C.; Vaucheret, H.; Robertson, D. Geminivirus VIGS of endogenous genes requires SGS2/SDE1 and SGS3 and defines a new branch in the genetic pathway for silencing in plants. Plant J. 2004, 38, 1004–1014. [CrossRef] [PubMed]
6150
Viruses 2015, 7, 6141–6151
27.
28. 29. 30. 31.
32. 33.
Abraham-Juarez, M.R.; Rocha-Granados, M.C.; Lopez, M.G.; Rivera-Bustamante, R.F.; Ochoa-Alejo, N. Virus-induced silencing of Comt, pAmt and Kas genes results in a reduction of capsaicinoid accumulation in chili pepper fruits. Planta 2008, 227, 681–695. [CrossRef] [PubMed] pCRr 2.1-TOPOr TA Vector—Subcloning Vector (Invitrogen, Carlsbad, CA, USA). Available online: https://www.lifetechnologies.com. Dellaporta, S.L.; Wood, J.; Hicks, J.B. A plant DNA minipreparation: Version II. Plant Mol. Biol. Report. 1983, 1, 19–21. [CrossRef] SAS Institute. SAS/STAT User’s Guide, Version 6, 4th ed.; SAS Institute: Cary, NC, USA, 1990. Park, C.-J.; An, J.-M.; Shin, Y.-C.; Kim, K.-J.; Lee, B.-J.; Paek, K.-H. Molecular characterization of pepper germin-like protein as the novel PR-16 family of pathogenesis-related proteins isolated during the resistance response to viral and bacterial infection. Planta 2004, 219, 797–806. [CrossRef] [PubMed] Lou, Y.; Baldwin, I.T. Silencing of a germin-like gene in Nicotiana attenuata improves performance of native herbivores. Plant Physiol. 2006, 140, 1126–1136. [CrossRef] [PubMed] Saucedo-García, M.; González-Solís, A.; Rodriguez-Mejía, P.; Olivera-Flores, T.J.; Vázquez-Santana, S.; Cahoon, E.B.; Gavilanes-Ruiz, M. Reactive oxygen species as transducers of sphinganine-mediated cell death pathway. Plant Signal. Behav. 2011, 6, 1616–1619. [CrossRef] [PubMed] © 2015 by the authors; licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons by Attribution (CC-BY) license (http://creativecommons.org/licenses/by/4.0/).
6151